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市场调查报告书
商品编码
1818040
量子电子感测设备市场预测(至 2032 年):按类型、部署平台、公司规模、技术、应用、最终用户和地区进行的全球分析Quantum Electronics & Sensing Devices Market Forecasts to 2032 - Global Analysis By Type, Deployment Platform, Enterprise Size, Technology, Application, End User and By Geography |
根据 Stratistics MRC 的数据,全球量子电子感测设备市场预计到 2025 年将达到 4,369 亿美元,到 2032 年将达到 1,2199 亿美元,预测期内的复合年增长率为 15.8%。
量子电子学和感测设备利用动态力学原理,例如迭加、纠缠和穿隧,实现比传统系统更高的精度、灵敏度和性能。这些技术结合了量子位元、光子电路和奈米级材料,用于探测、测量和操控原子和亚原子层面的物理现象。它们广泛应用于计量学、生物医学诊断和安全通讯,能够实现超灵敏探测、低杂讯讯号处理和即时资料撷取,为科学、工业和国防领域的下一代仪器仪表奠定了基础。
对前所未有的高精度和灵敏度的需求不断增长
量子电子装置和感测设备在探测磁场、重力和时间同步的微小变化方面拥有无与伦比的精度。这些功能对于非GPS导航、地下测绘和脑部影像等应用至关重要。随着传统感测器性能达到极限,业界正在转向量子技术,以满足日益增长的精度需求。各国政府为提升战略能力而推出的量子倡议和商业投资进一步推动了这项转变。
与传统技术的竞争
传统感测器应用广泛、经济高效,并拥有成熟的製造生态系统。然而,由于量子感测器初始成本高昂、扩充性有限且整合要求复杂,许多产业对采用量子感测器犹豫不决。此外,缺乏标准化通讯协定以及与现有系统的互通性也为其广泛应用带来了额外的挑战。这些因素正在减缓从旧有系统向量子平台的过渡。
加强与人工智慧和机器学习的融合
机器学习演算法可以透过校正杂讯、改进校准和实现即时决策来提升量子感测器的性能。这种融合将对自动驾驶汽车、智慧基础设施和医疗诊断等领域产生特别显着的影响,因为快速且准确的感测至关重要。随着人工智慧框架日益复杂,它们与量子设备的整合有望激发创新并开闢新的商业性途径。这种协同效应也吸引了跨学科研究和创投的关注。
智慧财产权和国家安全问题
世界各国政府正在实施出口管制并加强监管,以保护敏感的量子技术创新。量子感测器既可用于民用,也可用于军用,这增加了滥用和未授权存取存取的风险。此外,专利分散和权利要求重迭可能导致法律纠纷,并延迟商业化。这些风险需要强有力的网路安全措施和国际合作,以确保负责任的开发和部署。
新冠疫情对量子电子感测设备市场产生了微妙的影响。虽然最初的封锁措施扰乱了供应链,减缓了研发活动,但这场危机也凸显了先进感测技术在医疗保健和远距离诊断的重要性。量子感测器有助于提高诊断成像的准确性,并在临床环境中监测生理参数。此外,疫情加速了数位转型,并增加了人们对基于量子技术的安全通讯和资料完整性解决方案的兴趣。
预计量子感测器市场在预测期内将占据最大份额
量子感测器领域预计将在预测期内占据最大的市场份额,这得益于其无与伦比的极高精度物理现象测量能力。手錶、量子磁力仪和重力仪等技术已广泛应用于航太、国防和物理探勘。它们的高灵敏度和抗环境噪音能力使其成为策略应用的关键。该领域受益于持续的微型化努力以及与CMOS相容平台的集成,从而扩展了其在商业领域的可用性。
预计硅光电领域在预测期内将实现最高的复合年增长率
硅光电领域预计将在预测期内实现最高成长率,这得益于其在高速资料传输和紧凑型量子电路方面发挥的作用。这些元件利用基于光的讯号处理技术实现低延迟通讯和频宽频宽,使其成为量子运算和安全网路的理想选择。该领域也在快速创新混合整合技术,使光子晶片能够与量子处理器和感测器连接。
在政府资金、先进研究机构和蓬勃发展的新创企业新兴企业系统的推动下,北美预计将在预测期内占据最大的市场份额。该地区拥有多个重要的量子项目,包括国防级感测器开发和太空量子实验。学术界和产业界之间的紧密合作正在加速技术转移和商业化。此外,监管支持和战略伙伴关係正在巩固北美在该领域的主导地位。
预计亚太地区在预测期内的复合年增长率最高。中国、日本和印度等国家已启动国家倡议,建造量子基础设施并培养技术人才。该地区对先进导航系统、环境监测工具和安全通讯网路的需求不断增长,推动了相关技术的采用。随着各国政府重视技术主权,亚太地区正逐渐成为量子创新的活力中心。
According to Stratistics MRC, the Global Quantum Electronics & Sensing Devices Market is accounted for $436.9 billion in 2025 and is expected to reach $1,219.9 billion by 2032 growing at a CAGR of 15.8% during the forecast period. Quantum electronics and sensing devices utilize quantum mechanical principles such as superposition, entanglement, and tunneling to achieve enhanced precision, sensitivity, and performance beyond classical systems. These technologies incorporate quantum bits, photonic circuits, and nanoscale materials to detect, measure, or manipulate physical phenomena at atomic and subatomic levels. Widely applied in metrology, biomedical diagnostics, and secure communications, they enable ultra-sensitive detection, low-noise signal processing, and real-time data acquisition, forming the foundation for next-generation instrumentation across scientific, industrial, and defense sectors.
Increasing need for unprecedented precision and sensitivity
Quantum electronics and sensing devices offer unmatched accuracy in detecting minute changes in magnetic fields, gravitational forces, and time synchronization. These capabilities are vital for applications like GPS-denied navigation, subsurface mapping, and brain imaging. As conventional sensors reach their performance limits, industries are turning to quantum technologies to meet rising expectations for precision. This shift is further supported by national quantum initiatives and commercial investments aimed at enhancing strategic capabilities.
Competition from traditional technologies
Conventional sensors are widely available, cost-effective, and supported by mature manufacturing ecosystems. Many industries remain hesitant to adopt quantum alternatives due to high initial costs, limited scalability, and complex integration requirements. Additionally, the lack of standardized protocols and interoperability with existing systems poses challenges for widespread deployment. These factors collectively slow down the transition from legacy systems to quantum-enabled platforms.
Growing convergence with AI and machine learning
Machine learning algorithms can enhance the performance of quantum sensors by compensating for noise, improving calibration, and enabling real-time decision-making. This convergence is particularly impactful in autonomous vehicles, smart infrastructure, and medical diagnostics, where rapid and accurate sensing is critical. As AI frameworks become more sophisticated, their integration with quantum devices is expected to drive innovation and open new commercial pathways. This synergy is also attracting cross-disciplinary research and venture capital funding.
Intellectual property and national security concerns
Governments are implementing export controls and tightening regulations to safeguard sensitive quantum innovations. The dual-use nature of quantum sensors-applicable in both civilian and military domains heightens the risk of misuse or unauthorized access. Additionally, fragmented patent landscapes and overlapping claims can lead to legal disputes, slowing down commercialization. These risks necessitate robust cybersecurity measures and international cooperation to ensure responsible development and deployment.
The COVID-19 pandemic had a nuanced impact on the quantum electronics and sensing devices market. While initial lockdowns disrupted supply chains and delayed R&D activities, the crisis also underscored the importance of advanced sensing technologies in healthcare and remote diagnostics. Quantum sensors played a role in enhancing imaging precision and monitoring physiological parameters in clinical settings. Moreover, the pandemic accelerated digital transformation, prompting increased interest in quantum-enabled solutions for secure communications and data integrity.
The quantum sensors segment is expected to be the largest during the forecast period
The quantum sensors segment is expected to account for the largest market share during the forecast period due to their unparalleled ability to measure physical phenomena with extreme accuracy. Technologies such as atomic clocks, quantum magnetometers, and gravimeters are being deployed in aerospace, defense, and geophysical exploration. Their high sensitivity and resilience to environmental noise make them indispensable for strategic applications. The segment benefits from ongoing miniaturization efforts and integration with CMOS-compatible platforms, which are expanding their usability across commercial domains.
The silicon photonics segment is expected to have the highest CAGR during the forecast period
Over the forecast period, the silicon photonics segment is predicted to witness the highest growth rate driven by its role in enabling high-speed data transmission and compact quantum circuits. These devices leverage light-based signal processing to achieve low-latency communication and enhanced bandwidth, making them ideal for quantum computing and secure networks. The segment is witnessing rapid innovation in hybrid integration techniques, allowing photonic chips to interface with quantum processors and sensors.
During the forecast period, the North America region is expected to hold the largest market share attributed to robust government funding, advanced research institutions, and a thriving startup ecosystem. The region hosts several flagship quantum programs, including defense-grade sensor development and spaceborne quantum experiments. Strong collaborations between academia and industry are accelerating technology transfer and commercialization. Furthermore, regulatory support and strategic partnerships are reinforcing North America's dominance in this domain.
Over the forecast period, the Asia Pacific region is anticipated to exhibit the highest CAGRfueled by rising investments in quantum research and expanding industrial applications. Countries like China, Japan, and India are launching national initiatives to build quantum infrastructure and train skilled personnel. The region's growing demand for advanced navigation systems, environmental monitoring tools, and secure communication networks is driving adoption. As regional governments prioritize technological sovereignty, Asia Pacific is emerging as a dynamic hub for quantum innovation.
Key players in the market
Some of the key players in Quantum Electronics & Sensing Devices Market include ID Quantique SA, Campbell Scientific, Inc., LI-COR Biosciences, M Squared Lasers Ltd., Muquans SAS, Qnami AG, Teledyne Scientific & Imaging, Thorlabs, Inc., Oxford Instruments plc, QuSpin Inc., Zurich Instruments AG, AOSense, Inc., Qnnect LLC, QinetiQ Group plc, Bosch Quantum Sensing, and Infleqtion.
In June 2025, Campbell Scientific reported a contract to design, deliver and commission an AWOS (Automated Weather Observing System) for Beyla Airport, Guinea, showing continued deployment of their environmental/meteorological monitoring systems.
In June 2025, ID Quantique announced collaboration with Turkcell (and Juniper Networks) to deploy quantum-safe networking solutions, showcasing IDQ's quantum-secure crypto and photonics expertise for telecom infrastructure.
In January 2025, Thorlabs announced the acquisition/strategic partnership with Praevium Research (VCSEL/laser technology) a move to bring high-speed tunable VCSEL capability into Thorlabs' portfolio. Industry coverage framed this as strengthening Thorlabs' position in quantum/photonic component supply for imaging and communications.
Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.